a9d7a776c4
since the related code was removed by:
commit
|
||
---|---|---|
.. | ||
configs | ||
include | ||
kernel | ||
scripts | ||
src | ||
tools | ||
Kconfig | ||
README.txt |
README.txt ========== This README file discusses the port of NuttX to the Embedded Artists LPC4088 Developer's Kit board: See https://www.embeddedartists.com/products/lpc4088-developers-kit/ This board features the NXP LPC4088FET208 MCU on a carrier board called the LPC4088 OEM Board. CONTENTS ======== o LEDs o Buttons o Serial Console o Using OpenOCD with the Olimex ARM-USB-OCD o Loading Code with the ISP Board o Configuration LEDs ==== The LPC4088 OEM board has two user LEDs on GPIO pins: LED1 : Connected to P2[26] LED2 : Connected to P2[27] If CONFIG_ARCH_LEDS is not defined, then the user can control the LEDs in any way using the definitions provided in the board.h header file. If CONFIG_ARCH_LEDs is defined, then NuttX will control the 2 LEDs on the LPC4088 OEM board. The following definitions describe how NuttX controls the LEDs: LED1 LED2 LED3 LED4 LED_STARTED OFF OFF OFF OFF LED_HEAPALLOCATE ON OFF OFF OFF LED_IRQSENABLED OFF ON OFF OFF LED_STACKCREATED ON ON OFF OFF LED_INIRQ LED3 glows, on while in interrupt LED_SIGNAL LED3 glows, on while in signal handler LED_ASSERTION LED3 glows, on while in assertion LED_PANIC LED3 Flashes at 2Hz LED_IDLE LED glows: ON while active; OFF while sleeping Several additional LEDs are available on a PCA9532 port expander, which is not currently enabled. Buttons ======= The LPC4088 Developer's Kit supports a button: USER1 : Connected to P2[10] And a Joystick JOY_A : Connected to P2[23] JOY_B : Connected to P2[25] JOY_C : Connected to P2[26] JOY_D : Connected to P2[27] JOY_CTR : Connected to P2[22] These can be accessed using the definitions and interfaces defined in the board.h header file. Several additional buttons are available on a PCA9532 port expander, which is not currently enabled. Serial Console ============== By Default, UART0 is used as the serial console in all configurations. This may be connected to your computer via the onboard FT232 USB to UART chip. As an option, UART1 can also be used for the serial console. You might want, to do this, for example, if you use UART0 for the ISP function and you want to use a different UART for console output. UART1 can be configured as the serial console by changing the configuration as follows: System Type: CONFIG_LPC17_40_UART0=n : Disable UART0 if it is no longer used CONFIG_LPC17_40_UART1=y : Enable UART1 Drivers: CONFIG_UART1_SERIAL_CONSOLE=y : Setup up the UART1 configuration CONFIG_UART1_RXBUFSIZE=256 CONFIG_UART1_TXBUFSIZE=256 CONFIG_UART1_BAUD=115200 CONFIG_UART1_BITS=8 CONFIG_UART1_PARITY=0 CONFIG_UART1_2STOP=0 In this configuration using UART1, the jumpers JP12 and JP13 must be set to short pins 1 and 2. UART 1 will then be available on the DB9 connector J17. Using OpenOCD with the Olimex ARM-USB-OCD ========================================= Building OpenOCD under Cygwin: Refer to boards/olimex-lpc1766stk/README.txt Installing OpenOCD in Ubuntu Linux: sudo apt-get install openocd Helper Scripts. I have been using the Olimex ARM-USB-OCD debugger. OpenOCD requires a configuration file. I keep the one I used last here: boards/arm/lpc17xx_40xx/lpc4088-devkit/tools/lpc4088-devkit.cfg However, the "correct" configuration script to use with OpenOCD may change as the features of OpenOCD evolve. So you should at least compare that lpc4088-devkit.cfg file with configuration files in /usr/share/openocd/scripts. As of this writing, the configuration files of interest were: /usr/local/share/openocd/scripts/interface/openocd-usb.cfg This is the configuration file for the Olimex ARM-USB-OCD debugger. Select a different file if you are using some other debugger supported by OpenOCD. /usr/local/share/openocd/scripts/board/? I don't see a board configuration file for the LPC4088 developer's kit. /usr/local/share/openocd/scripts/target/lpc40xx.cfg This is the configuration file for the LPC4088 target. It just sets up a few parameters then sources lpc1xxx.cfg /usr/local/share/openocd/scripts/target/lpc1xxx.cfg This is the generic LPC configuration for the LPC1xxx family. It is included by lpc40xx.cfg. NOTE: These files could also be located under /usr/share in some installations. They could be most anywhwere if you are using a windows version of OpenOCD. boards/arm/lpc17xx_40xx/lpc4088-devkit/tools/lpc4088-devkit.cfg This is simply openocd-usb.cfg, lpc40xx.cfg, and lpc1xxx.cfg concatenated into one file for convenience. Don't use it unless you have to. There is also a script on the tools/ directory that I use to start the OpenOCD daemon on my system called oocd.sh. That script will probably require some modifications to work in another environment: - Possibly the value of OPENOCD_PATH and TARGET_PATH - It assumes that the correct script to use is the one at boards/arm/lpc17xx_40xx/lpc4088-devkit/tools/lpc4088-devkit.cfg Starting OpenOCD Then you should be able to start the OpenOCD daemon as follows. This assumes that you have already CD'ed to the NuttX build directory and that you have set the full path to the boards/arm/lpc17xx_40xx/lpc4088-devkit/tools in your PATH environment variable: oocd.sh $PWD or, if the PATH variable is not so configured: boards/arm/lpc17xx_40xx/lpc4088-devkit/tools/oocd.sh $PWD Connecting GDB Once the OpenOCD daemon has been started, you can connect to it via GDB using the following GDB command: arm-nuttx-elf-gdb (gdb) target remote localhost:3333 NOTE: The name of your GDB program may differ. For example, with the CodeSourcery toolchain, the ARM GDB would be called arm-none-eabi-gdb. OpenOCD will support several special 'monitor' sub-commands. You can use the 'monitor' (or simply 'mon') command to invoke these sub- commands. These GDB commands will send comments to the OpenOCD monitor. Here are a couple that you will need to use: (gdb) monitor reset (gdb) monitor halt NOTES: 1. The MCU must be halted using 'monitor halt' prior to loading code. 2. 'monitor reset' will restart the processor after loading code. 3. The 'monitor' command can be abbreviated as just 'mon'. After starting GDB, you can load the NuttX ELF file like this: (gdb) mon halt (gdb) load nuttx NOTES: 1. NuttX should have been built so that it has debugging symbols (by setting CONFIG_DEBUG_SYMBOLS=y in the .config file). 2. The MCU must be halted prior to loading code. 3. I find that there are often undetected write failures when using the Olimex ARM-USB-OCD debugber and that if you start the program with a bad FLASH failure, it will lock up OpenOCD. I usually oad nuttx twice, restarting OpenOCD in between in order to assure good FLASH contents: (gdb) mon halt (gdb) load nuttx (gdb) mon reset Exit GDB, kill the OpenOCD server, recycle power on the board, restart the OpenOCD server and GDB, then: (gdb) mon halt (gdb) load nuttx (gdb) mon reset Other debuggers may not have these issues and such drastic steps may not be necessary. Loading Code with the ISP Board =============================== Users can also load code onto the board using the UART0 USB VCOM chip. I use the FlashMagic program for Windows available here: http://www.flashmagictool.com/ . It is so easy to use that no further explanation should be necessary: Just select the LPC4088, the ISP COM port, and the NuttX .hex file and program it. CONFIGURATION ============= Information Common to All Configurations ---------------------------------------- 1. These configurations use the mconf-based configuration tool. To change this configuration using that tool, you should: a. Build and install the kconfig-mconf tool. See nuttx/README.txt see additional README.txt files in the NuttX tools repository README.txt. b. Execute 'make menuconfig' in nuttx/ in order to start the reconfiguration process. 2. Most (but not all) configurations use the "GNU Tools for ARM Embedded Processors" that is maintained by ARM: https://developer.arm.com/open-source/gnu-toolchain/gnu-rm unless otherwise stated. That toolchain selection can easily be reconfigured using 'make menuconfig'. Here are the relevant current settings: Build Setup: CONFIG_HOST_WINDOWS=y : Window environment CONFIG_WINDOWS_CYGWIN=y : Cywin under Windows System Type -> Toolchain: CONFIG_ARMV7M_TOOLCHAIN_GNU_EABIW=y : GNU ARM EABI toolchain 3. By Default, UART0 is used as the serial console in all configurations. This may be connected to your computer via an external RS-232 driver or via the on board USB VCOM chip. See the section above entitled "Serial Console" for other options. 4. An LCD is available for this board, but I don't have one to test with. If you wish to use any of the configurations below which utilize the LCD, you will need to tweak the LCD pin definitions in board.h. Configuration Directories ------------------------- knsh ---- This is identical to the nsh configuration below except that NuttX is built as a kernel-mode, monolithic module and the user applications are built separately. Is is recommended to use a special make command; not just 'make' but make with the following two arguments: make pass1 pass2 In the normal case (just 'make'), make will attempt to build both user- and kernel-mode blobs more or less interleaved. This actual works! However, for me it is very confusing so I prefer the above make command: Make the user-space binaries first (pass1), then make the kernel-space binaries (pass2) 1. Uses the older, OABI, buildroot toolchain. But that is easily reconfigured: CONFIG_ARMV7M_TOOLCHAIN_BUILDROOT=y : Buildroot toolchain CONFIG_ARMV7M_OABI_TOOLCHAIN=y : Older, OABI toolchain 2. This configuration has DMA-based SD card support enabled by default. That support can be disabled as follow: CONFIG_LPC17_40_GPDMA=n : No DMA CONFIG_ARCH_DMA=n CONFIG_LPC17_40_SDCARD=n : No SD card driver CONFIG_SDIO_DMA=n : No SD card DMA CONFIG_MMCSD=n : No MMC/SD driver support CONFIG_FS_FAT=n : No FAT file system support 3. At the end of the build, there will be several files in the top-level NuttX build directory: PASS1: nuttx_user.elf - The pass1 user-space ELF file nuttx_user.hex - The pass1 Intel HEX format file (selected in defconfig) User.map - Symbols in the user-space ELF file PASS2: nuttx - The pass2 kernel-space ELF file nuttx.hex - The pass2 Intel HEX file (selected in defconfig) System.map - Symbols in the kernel-space ELF file Loading these .elf files with OpenOCD is tricky. It appears to me that when nuttx_user.elf is loaded, it destroys the nuttx image in FLASH. But loading the nuttx ELF does not harm the nuttx_user.elf in FLASH. Conclusion: Always load nuttx_user.elf before nuttx. Just to complicate matters, it is sometimes the case that you need load objects twice to account for write failures. I have not yet found a simple foolproof way to reliably get the code into FLASH. 4. Combining .hex files. If you plan to use the .hex files with your debugger or FLASH utility, then you may need to combine the two hex files into a single .hex file. Here is how you can do that. a. The 'tail' of the nuttx.hex file should look something like this (with my comments added): $ tail nuttx.hex # 00, data records ... :10 9DC0 00 01000000000800006400020100001F0004 :10 9DD0 00 3B005A0078009700B500D400F300110151 :08 9DE0 00 30014E016D0100008D # 05, Start Linear Address Record :04 0000 05 0800 0419 D2 # 01, End Of File record :00 0000 01 FF Use an editor such as vi to remove the 05 and 01 records. b. The 'head' of the nuttx_user.hex file should look something like this (again with my comments added): $ head nuttx_user.hex # 04, Extended Linear Address Record :02 0000 04 0801 F1 # 00, data records :10 8000 00 BD89 01084C800108C8110208D01102087E :10 8010 00 0010 00201C1000201C1000203C16002026 :10 8020 00 4D80 01085D80010869800108ED83010829 ... Nothing needs to be done here. The nuttx_user.hex file should be fine. c. Combine the edited nuttx.hex and un-edited nuttx_user.hex file to produce a single combined hex file: $ cat nuttx.hex nuttx_user.hex >combined.hex Then use the combined.hex file with the to write the FLASH image. If you do this a lot, you will probably want to invest a little time to develop a tool to automate these steps. STATUS: 2019-04-23: Untested with LPC4088. nsh --- Configures the NuttShell (nsh) located at examples/nsh. The Configuration enables both the serial NSH interface as well as the telnet interface over ethernet, with an IP address assigned via DHCP.